waves at boundaries
DESCRIPTION
Waves at Boundaries. Waves at Boundaries. A wave transmits energy through a medium Eventually that wave will reach a boundary A boundary is an obstacle or even another medium that the wave reaches as it travels. Waves at Boundaries. What happens at the wave boundary? - PowerPoint PPT PresentationTRANSCRIPT
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WAVES AT BOUNDARIES
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WAVES AT BOUNDARIES• A wave transmits energy
through a medium
• Eventually that wave will reach a boundary
• A boundary is an obstacle or even another medium that the wave reaches as it travels
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WAVES AT BOUNDARIES
• What happens at the wave boundary?
1. The initial wave travels at the boundary. This is the incident wave.
2. A portion of the energy flows into the new medium. This is called the transmitted wave.
3. A portion of the energy is reflected. This is called the reflected wave.
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WAVES AT BOUNDARIES
• The incident wave and reflected wave can have 2 situations:1. Fixed End2. Free End
• The transmitted wave depends on the density of the new medium
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FIXED END REFLECTION
• Fixed end reflection is when one end of the medium is attached to an object that cannot move
• Think of a rope attached to a table
Let’s talk about sending a wave pulse through this rope to help you visualize
• The incident wave travels through the medium and hits the boundary
• This will created a transmitted and wave and reflected wave
• Let’s think about what will happen to the reflected wave…
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FIXED END REFLECTION• The rope is pulling up at the fixed end.
• For every reaction there is an equal and opposite reaction• The fixed end pulls down on the rope
• The reflected wave comes back through the rope but has an inverted amplitude
• The wavelength of the reflected wave is the same as the wavelength of the incident wave
• The speed of the wave is still the same. Remember, speed depends on wavelength and frequency. These do not change.
• The amplitude of the reflected wave is less than the amplitude of the incident wave• Remember, the amplitude squared of a mechanical wave is proportional to the
energy of the wave. Some of the energy was sent to create a transmitted wave.
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FREE END REFLECTION
• When the end of a medium is not attached and is free to move, we consider this the case of free-end reflection
• Once again, let’s think about what happens when a wave pulse reaches the end of the rope
• It will create a reflected and transmitted wave again.
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FREE END REFLECTION• The rope pulls up at the free end but nothing pulls down.
• The reflected wave returns with but does not have an inverted amplitude
• The wavelength remains the same for the reflected pulse
• The speed of the wave remains the same
• The amplitude is not inversed and is less than the incident wave
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TRANSMITTED WAVE
• No we will look at the transmitted wave at a boundary
• The transmitted wave does not depend on free or fixed end
• The transmitted wave depends only on the density of the medium for the incident wave and the density of the medium for the transmitted wave
• The transmitted wave can be in either:1. Higher density medium2. Lower density medium
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HIGH DENSITY MEDIUM FOR TRANSMITTED WAVE
• We will examine what happens as a wave passes into a higher density medium from a lower density medium
• As the wave reaches the boundary, some of the energy will continue into the new medium (transmitted wave) and some of the energy will be bounced back (reflected wave)
• The transmitted wave will:• Travel with a slower speed compared to the
incident wave• Have a shorter wavelength than the
incident wave• Amplitude is in the same direction as the
incident wave • Frequency stays the same
• The reflected wave will:• Travel with a same speed as the incident
wave• Have the same wavelength than the
incident wave• Have an inverted amplitude compared to
the incident wave • Frequency stays the same
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LOWER DENSITY MEDIUM FOR TRANSMITTED WAVE
• We will examine what happens as a wave passes into a lower density medium from a lower density medium
• The transmitted wave will:• Travel with a faster speed compared to the
incident wave• Have a longer wavelength than the incident
wave• Amplitude is in the same direction as the
incident wave • Frequency stays the same
• The reflected wave will:• Travel with a same speed as the incident
wave• Have the same wavelength than the
incident wave• Amplitude is in the same direction as the
incident wave • Frequency stays the same
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FREQUENCY, VELOCITY & AMPLITUDE
• Frequency• The frequency of the wave will be the same in both mediums.
• Velocity• The velocity depends on the properties of each medium and
therefore will be different in each medium. (less dense = faster, more dense = slower).
• Amplitude • The amplitude is directly proportional to the velocity. (if v
higher, amplitude is greater. If v is lower, amplitude is smaller)
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CALCULATIONS INVOLVING TRANSMISSION OF WAVES
• From the information we just went through, we should notice that the velocity and amplitude are proportional to each other when a wave changes mediums• If the new medium is less dense, the velocity and amplitude increase• If the new medium is more dense, the velocity and amplitude decrease
• We also learned that frequency remains constant when a wave changes media
• One thing we haven’t discussed yet is what happens to the wavelength when a wave changes media• Recall the “Universal Wave Equation”: v = fλ • If we know that the velocity will change in a new medium, then the
wavelength must also change in a similar way in order for the relationship v = fλ to remain true.
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CALCULATIONS INVOLVING TRANSMISSION OF WAVES
• When solving a question where a wave changes mediums, remember that frequency is constant. Solve for it first, then use it to solve for whatever you need.
• Example: A tow rope is connected to a slinky. A wave travelling at 1.50 m/s is introduced to the tow rope. After the wave is transmitted to the slinky, the wave is travelling at 5.35 m/s with a wavelength of 3.00 m. What is the initial wavelength of the wave in the tow rope?• You have enough info to solve for “f” in the slinky
• v = fλ• f = v/λ• f = 5.35 m/s
3.00 mf = 1.78 Hz
• Now, use that value of “f” to solve for the unknown wavelength• v = fλ• Λ = v/f• Λ = 1.50 m/s
1.78 HzΛ = 0.843 m
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CALCULATIONS INVOLVING TRANSMISSION OF WAVES
• What we should also realize from this example is the following relationship:
Vi= Vf
λi λf
• Where:• Vi = initial velocity• Λi = initial wavelength• Vf = final velocity• Λf = final wavelength
• From the previous example• Vi = 5.35 m/s • Λi = 3.00 m• Vf = 1.50 m/s • Λf = ?